Numerical and Experimental Determination of Selected Performance Indicators of the Liquid Flat-Plate Solar Collector under Outdoor Conditions

Energies Pub Date : 2024-07-13 DOI:10.3390/en17143454
W. Zima, Ł. Mika, K. Sztekler
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Abstract

The paper proposes applying an in-house mathematical model of a liquid flat-plate solar collector to calculate the collector time constant. The described model, proposed for the first time in an earlier study, is a one-dimensional distributed parameter model enabling simulations of the collector operation under arbitrarily variable boundary conditions. The model is based on the solution of energy balance equations for all collector components. The formulated differential equations are solved iteratively using an implicit difference scheme. To obtain a stable numerical solution, it is necessary to use appropriate steps of time and spatial division. These were found by comparing the results obtained from the model with the results of the analytical solution available in the literature for the transient state, which constitutes the novelty of the present study. The accuracy of the results obtained from the model was verified experimentally by comparing the measured and calculated history of the fluid temperature at the outlet of the collector. The calculation of the collector time constant is proposed in the paper as an example of the model’s practical application. The results of the time constant calculation were compared with the values obtained experimentally on the test stand. This is another novelty of the presented research. The analysed collector instantaneous efficiency was then calculated for selected outdoor conditions. The presented mathematical model can also be used to verify the correctness of the collector operation. By comparing, on an ongoing basis, the measured and calculated values of the fluid temperature at the collector outlet, conclusions can be drawn about the process of solar glass fouling or glycol gelling. The simplicity of the model and the low computational demands enable such comparisons in an online mode.
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室外条件下液体平板太阳能集热器部分性能指标的数值和实验测定
本文建议应用内部的液态平板太阳能集热器数学模型来计算集热器时间常数。该模型是在早先的一项研究中首次提出的,它是一种一维分布式参数模型,可在任意变化的边界条件下模拟集热器的运行。该模型基于所有集热器组件的能量平衡方程求解。所制定的微分方程采用隐式差分方案迭代求解。要获得稳定的数值解,必须使用适当的时间和空间划分步骤。这些都是通过将模型得到的结果与文献中对瞬态的分析求解结果进行比较而得出的,这也是本研究的新颖之处。通过比较集热器出口处流体温度的测量值和计算值,实验验证了模型结果的准确性。文中提出了集热器时间常数的计算方法,作为模型实际应用的一个实例。时间常数的计算结果与试验台上的实验值进行了比较。这是本文研究的另一个新颖之处。分析后的集热器瞬时效率是根据选定的室外条件计算得出的。所提出的数学模型还可用于验证集热器运行的正确性。通过持续比较集热器出口流体温度的测量值和计算值,可以得出太阳能玻璃结垢或乙二醇胶凝过程的结论。由于模型简单,计算要求低,因此可以在在线模式下进行这种比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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